A central topic in single-atom catalysis
is building strong interactions
between single atoms and the support for stabilization. Herein we
report the preparation of stabilized single-atom catalysts via a simultaneous
self-reduction stabilization process at room temperature using ultrathin
two-dimensional Ti3–x
C2T
y
MXene nanosheets characterized by abundant
Ti-deficit vacancy defects and a high reducing capability. The single
atoms therein form strong metal–carbon bonds with the Ti3–x
C2T
y
support and are therefore stabilized onto the sites previously
occupied by Ti. Pt-based single-atom catalyst (SAC) Pt1/Ti3–x
C2T
y
offers a green route to utilizing greenhouse gas
CO2, via the formylation of amines, as a C1 source
in organic synthesis. DFT calculations reveal that, compared to Pt
nanoparticles, the single Pt atoms on Ti3–x
C2T
y
support feature
partial positive charges and atomic dispersion, which helps to significantly
decrease the adsorption energy and activation energy of silane, CO2, and aniline, thereby boosting catalytic performance. We
believe that these results would open up new opportunities for the
fabrication of SACs and the applications of MXenes in organic synthesis.
Efficient
water electrolysis for hydrogen production constitutes
a key segment for the upcoming hydrogen economy, but has been impeded
by the lack of high-performance and low-cost electrocatalysts for,
ideally, simultaneously expediting the kinetics of both hydrogen and
oxygen evolution reactions (HER and OER). In this study, the favored
binding energetics of OER and HER reaction intermediates on iron-doped
nickel phosphides are first predicted by density functional theory
(DFT) simulations, and then experimentally verified through the fabrication
of Fe-doped Ni2P nanoparticles embedded in carbon nanotubes
using metal–organic framework (MOF) arrays on nickel foam as
the structural template. Systematic investigations on the effect of
phosphorization and Fe doping reveal that while the former endows
a larger benefit on OER than on HER, the latter enables not only modulating
the electronic structure, but also tuning the micromorphology of the
catalyst, synergistically leading to both enhanced HER and OER. As
a result, extraordinary performances of constant water electrolysis
are demonstrated requiring only a cell voltage of 1.66 V to afford
a current density of 500 mA cm–2, far outperforming
the benchmark electrode couple composed of Pt/C and RuO2. Postelectrolysis characterizations combined with DFT inspection
further reveal that while the Fe-doped Ni2P species are
mostly retained after prolonged HER, they are in situ converted to
Fe/P-doped γ-NiOOH during OER, serving as the actual OER active
sites with high activity.
Solid‐state Li metal batteries (SSLMBs) have attracted considerable interests due to their promising energy density as well as high safety. However, the realization of a well‐matched Li metal/solid‐state electrolyte (SSE) interface remains challenging. Herein, we report g‐C3N4 as a new interface enabler. We discover that introducing g‐C3N4 into Li metal can not only convert the Li metal/garnet‐type SSE interface from point contact to intimate contact but also greatly enhance the capability to suppress the dendritic Li formation because of the greatly enhanced viscosity, decreased surface tension of molten Li, and the in situ formation of Li3N at the interface. Thus, the resulting Li‐C3N4|SSE|Li‐C3N4 symmetric cell gives a significantly low interfacial resistance of 11 Ω cm2 and a high critical current density (CCD) of 1500 μA cm−2. In contrast, the same symmetric cell configuration with pristine Li metal electrodes has a much larger interfacial resistance (428 Ω cm2) and a much lower CCD (50 μA cm−2).
Reversible oxygen conversion is important for various green energy technologies. Herein we synthesize a series of bimetallic coordination polymers by varying the Ni/Co ratio and using HITP (HITP=2,3,6,7,10,11‐hexaiminotriphenylene) as the ligand, to interrogate the role of metal centres in modulating the activity of the oxygen reduction reaction (ORR). Co3HITP2 and Ni3HITP2 are compared. Unpaired 3d electrons in Co3HITP2 result in less coplanarity but more radical character. Thus, despite of a reduced crystallinity and conductivity, the best ORR activity, comparable to 20 % Pt/C, is obtained for Co3HITP2, showing the 3d orbital configuration of the metal centre promotes ORR. Experimental and DFT studies show a transition of ORR pathway from four‐electron for Co3HITP2 to two‐electron for Ni3HITP2. Rechargeable zinc–air batteries using Co3HITP2 as the air cathode catalyst demonstrate excellent energy efficiency and stability.
Single Fe atom dispersed carbon nanostructures show promising oxygen reduction reaction (ORR) activities for renewable energy applications. Nevertheless, the microenvironment of the single Fe atoms needs to be further engineered to optimize the catalytic performance, which is challenging. In this work, we develop a NaCltemplate pyrolysis method to fabricate single Fe atom catalysts with atomically dispersed Fe−heteroatom (N, S) bridge sites anchored on carbon nanosheets. The N and S coordinated Fe atomic sites (FeN 3 S) are found to induce charge redistribution, lowering the binding strength of oxygenated reaction intermediates and leading to fast reaction kinetics and good oxygen reduction activity. Our work provides an effective method to regulate the microenvironment of single-atom catalysts for optimizing electrocatalytic performance.
The efficient utilization of near‐infrared (NIR) light for photocatalytic hydrogen generation is vitally important to both solar hydrogen energy and hydrogen medicine, but remains a challenge at present, owing to the strict requirement of the semiconductor for high NIR responsiveness, narrow bandgap, and suitable redox potentials. Here, an NIR‐active carbon/potassium‐doped red polymeric carbon nitride (RPCN) is achieved for by using a similar‐structure dopant as the melamine (C3H6N6) precursor with the solid KCl. The homogeneous and high incorporation of carbon and potassium remarkably narrows the bandgap of carbon nitride (1.7 eV) and endows RPCN with a high NIR‐photocatalytic activity for H2 evolution from water at the rate of 140 µmol h−1 g−1 under NIR irradiation (700 nm ≤ λ ≤ 780 nm), and the apparent quantum efficiency is high as 0.84% at 700 ± 10 nm (and 13% at 500 ± 10 nm). A proof‐of‐concept experiment on a tumor‐bearing mouse model verifies RPCN as being capable of intratumoral NIR‐photocatalytic hydrogen generation and simultaneous glutathione deprivation for safe and high‐efficacy drug‐free cancer therapy. The results shed light on designing efficient photocatalysts to capture the full spectrum of solar energy, and also pioneer a new pathway to develop NIR photocatalysts for hydrogen therapy of major diseases.
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